connectivity_data.cpp

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/*
 * This program source code file is part of KICAD, a free EDA CAD application.
 *
 * Copyright (C) 2017 CERN
 * Copyright (C) 2018-2020 KiCad Developers, see AUTHORS.txt for contributors.
 * @author Tomasz Wlostowski <[email protected]>
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, you may find one here:
 * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
 * or you may search the http://www.gnu.org website for the version 2 license,
 * or you may write to the Free Software Foundation, Inc.,
 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
 */

#ifdef PROFILE
#include <profile.h>
#endif

#include <thread>
#include <algorithm>
#include <future>

#include <connectivity/connectivity_data.h>
#include <connectivity/connectivity_algo.h>
#include <connectivity/from_to_cache.h>

#include <ratsnest/ratsnest_data.h>
#include <trigo.h>

CONNECTIVITY_DATA::CONNECTIVITY_DATA()
{
 m_connAlgo.reset( new CN_CONNECTIVITY_ALGO );
 m_progressReporter = nullptr;
 m_fromToCache.reset( new FROM_TO_CACHE );
}


CONNECTIVITY_DATA::CONNECTIVITY_DATA( const std::vector<BOARD_ITEM*>& aItems, bool aSkipRatsnest )
 : m_skipRatsnest( aSkipRatsnest )
{
 Build( aItems );
 m_progressReporter = nullptr;
 m_fromToCache.reset( new FROM_TO_CACHE );
}


CONNECTIVITY_DATA::~CONNECTIVITY_DATA()
{
 Clear();
}


bool CONNECTIVITY_DATA::Add( BOARD_ITEM* aItem )
{
 m_connAlgo->Add( aItem );
 return true;
}


bool CONNECTIVITY_DATA::Remove( BOARD_ITEM* aItem )
{
 m_connAlgo->Remove( aItem );
 return true;
}


bool CONNECTIVITY_DATA::Update( BOARD_ITEM* aItem )
{
 m_connAlgo->Remove( aItem );
 m_connAlgo->Add( aItem );
 return true;
}


void CONNECTIVITY_DATA::Build( BOARD* aBoard, PROGRESS_REPORTER* aReporter )
{
 m_connAlgo.reset( new CN_CONNECTIVITY_ALGO );
 m_connAlgo->Build( aBoard, aReporter );

 m_netclassMap.clear();

 for( NETINFO_ITEM* net : aBoard->GetNetInfo() )
 if( net->GetNetClass()->GetName() != NETCLASS::Default )
 m_netclassMap[ net->GetNetCode() ] = net->GetNetClass()->GetName();

 RecalculateRatsnest();
}


void CONNECTIVITY_DATA::Build( const std::vector<BOARD_ITEM*>& aItems )
{
 m_connAlgo.reset( new CN_CONNECTIVITY_ALGO );
 m_connAlgo->Build( aItems );

 RecalculateRatsnest();
}


void CONNECTIVITY_DATA::Move( const VECTOR2I& aDelta )
{
 m_connAlgo->ForEachAnchor( [&aDelta]( CN_ANCHOR& anchor )
 {
 anchor.Move( aDelta );
 } );
}


void CONNECTIVITY_DATA::updateRatsnest()
{
 #ifdef PROFILE
 PROF_COUNTER rnUpdate( "update-ratsnest" );
 #endif
 std::vector<RN_NET*> dirty_nets;

 // Start with net 1 as net 0 is reserved for not-connected
 // Nets without nodes are also ignored
 std::copy_if( m_nets.begin() + 1, m_nets.end(), std::back_inserter( dirty_nets ),
 [] ( RN_NET* aNet ) { return aNet->IsDirty() && aNet->GetNodeCount() > 0; } );

 // We don't want to spin up a new thread for fewer than 8 nets (overhead costs)
 size_t parallelThreadCount = std::min<size_t>( std::thread::hardware_concurrency(),
 ( dirty_nets.size() + 7 ) / 8 );

 std::atomic<size_t> nextNet( 0 );
 std::vector<std::future<size_t>> returns( parallelThreadCount );

 auto update_lambda = [&nextNet, &dirty_nets]() -> size_t
 {
 for( size_t i = nextNet++; i < dirty_nets.size(); i = nextNet++ )
 dirty_nets[i]->Update();

 return 1;
 };

 if( parallelThreadCount == 1 )
 update_lambda();
 else
 {
 for( size_t ii = 0; ii < parallelThreadCount; ++ii )
 returns[ii] = std::async( std::launch::async, update_lambda );

 // Finalize the ratsnest threads
 for( size_t ii = 0; ii < parallelThreadCount; ++ii )
 returns[ii].wait();
 }

 #ifdef PROFILE
 rnUpdate.Show();
 #endif /* PROFILE */
}


void CONNECTIVITY_DATA::addRatsnestCluster( const std::shared_ptr<CN_CLUSTER>& aCluster )
{
 auto rnNet = m_nets[ aCluster->OriginNet() ];

 rnNet->AddCluster( aCluster );
}


void CONNECTIVITY_DATA::RecalculateRatsnest( BOARD_COMMIT* aCommit )
{
 m_connAlgo->PropagateNets( aCommit );

 int lastNet = m_connAlgo->NetCount();

 if( lastNet >= (int) m_nets.size() )
 {
 unsigned int prevSize = m_nets.size();
 m_nets.resize( lastNet + 1 );

 for( unsigned int i = prevSize; i < m_nets.size(); i++ )
 m_nets[i] = new RN_NET;
 }

 auto clusters = m_connAlgo->GetClusters();

 int dirtyNets = 0;

 for( int net = 0; net < lastNet; net++ )
 {
 if( m_connAlgo->IsNetDirty( net ) )
 {
 m_nets[net]->Clear();
 dirtyNets++;
 }
 }

 for( const auto& c : clusters )
 {
 int net = c->OriginNet();

 // Don't add intentionally-kept zone islands to the ratsnest
 if( c->IsOrphaned() && c->Size() == 1 )
 {
 if( dynamic_cast<CN_ZONE_LAYER*>( *c->begin() ) )
 continue;
 }

 if( m_connAlgo->IsNetDirty( net ) )
 {
 addRatsnestCluster( c );
 }
 }

 m_connAlgo->ClearDirtyFlags();

 if( !m_skipRatsnest )
 updateRatsnest();
}


void CONNECTIVITY_DATA::BlockRatsnestItems( const std::vector<BOARD_ITEM*>& aItems )
{
 std::vector<BOARD_CONNECTED_ITEM*> citems;

 for( auto item : aItems )
 {
 if( item->Type() == PCB_FOOTPRINT_T )
 {
 for( PAD* pad : static_cast<FOOTPRINT*>(item)->Pads() )
 citems.push_back( pad );
 }
 else
 {
 if( auto citem = dynamic_cast<BOARD_CONNECTED_ITEM*>( item ) )
 citems.push_back( citem );
 }
 }

 for( const auto& item : citems )
 {
 if ( m_connAlgo->ItemExists( item ) )
 {
 auto& entry = m_connAlgo->ItemEntry( item );

 for( const auto& cnItem : entry.GetItems() )
 {
 for( auto anchor : cnItem->Anchors() )
 anchor->SetNoLine( true );
 }
 }
 }
}


int CONNECTIVITY_DATA::GetNetCount() const
{
 return m_connAlgo->NetCount();
}


void CONNECTIVITY_DATA::FindIsolatedCopperIslands( ZONE* aZone, std::vector<int>& aIslands )
{
 // TODO(JE) ZONES
#if 0
 m_connAlgo->FindIsolatedCopperIslands( aZone, aIslands );
#endif
}

void CONNECTIVITY_DATA::FindIsolatedCopperIslands( std::vector<CN_ZONE_ISOLATED_ISLAND_LIST>& aZones )
{
 m_connAlgo->FindIsolatedCopperIslands( aZones );
}


void CONNECTIVITY_DATA::ComputeDynamicRatsnest( const std::vector<BOARD_ITEM*>& aItems,
 const CONNECTIVITY_DATA* aDynamicData )
{
 if( !aDynamicData )
 return;

 m_dynamicRatsnest.clear();

 // This gets connections between the stationary board and the
 // moving selection
 for( unsigned int nc = 1; nc < aDynamicData->m_nets.size(); nc++ )
 {
 auto dynNet = aDynamicData->m_nets[nc];

 if( dynNet->GetNodeCount() != 0 )
 {
 auto ourNet = m_nets[nc];
 CN_ANCHOR_PTR nodeA, nodeB;

 if( ourNet->NearestBicoloredPair( *dynNet, nodeA, nodeB ) )
 {
 RN_DYNAMIC_LINE l;
 l.a = nodeA->Pos();
 l.b = nodeB->Pos();
 l.netCode = nc;

 m_dynamicRatsnest.push_back( l );
 }
 }
 }

 // This gets the ratsnest for internal connections in the moving set
 const auto& edges = GetRatsnestForItems( aItems );

 for( const auto& edge : edges )
 {
 const auto& nodeA = edge.GetSourceNode();
 const auto& nodeB = edge.GetTargetNode();
 RN_DYNAMIC_LINE l;

 // Use the parents' positions
 l.a = nodeA->Parent()->GetPosition();
 l.b = nodeB->Parent()->GetPosition();
 l.netCode = 0;
 m_dynamicRatsnest.push_back( l );
 }
}


void CONNECTIVITY_DATA::ClearDynamicRatsnest()
{
 m_connAlgo->ForEachAnchor( []( CN_ANCHOR& anchor )
 {
 anchor.SetNoLine( false );
 } );
 HideDynamicRatsnest();
}


void CONNECTIVITY_DATA::HideDynamicRatsnest()
{
 m_dynamicRatsnest.clear();
}


void CONNECTIVITY_DATA::PropagateNets( BOARD_COMMIT* aCommit, PROPAGATE_MODE aMode )
{
 m_connAlgo->PropagateNets( aCommit, aMode );
}


bool CONNECTIVITY_DATA::IsConnectedOnLayer( const BOARD_CONNECTED_ITEM *aItem, int aLayer,
 std::vector<KICAD_T> aTypes ) const
{
 CN_CONNECTIVITY_ALGO::ITEM_MAP_ENTRY &entry = m_connAlgo->ItemEntry( aItem );

 auto matchType = [&]( KICAD_T aItemType )
 {
 if( aTypes.empty() )
 return true;

 return std::count( aTypes.begin(), aTypes.end(), aItemType ) > 0;
 };

 for( CN_ITEM* citem : entry.GetItems() )
 {
 for( CN_ITEM* connected : citem->ConnectedItems() )
 {
 if( connected->Valid()
 && connected->Layers().Overlaps( aLayer )
 && connected->Net() == aItem->GetNetCode()
 && matchType( connected->Parent()->Type() ) )
 {
 return true;
 }
 }
 }

 return false;
}


unsigned int CONNECTIVITY_DATA::GetUnconnectedCount() const
{
 unsigned int unconnected = 0;

 for( auto net : m_nets )
 {
 if( !net )
 continue;

 const auto& edges = net->GetUnconnected();

 if( edges.empty() )
 continue;

 unconnected += edges.size();
 }

 return unconnected;
}


void CONNECTIVITY_DATA::Clear()
{
 for( auto net : m_nets )
 delete net;

 m_nets.clear();
}


const std::vector<BOARD_CONNECTED_ITEM*> CONNECTIVITY_DATA::GetConnectedItems(
 const BOARD_CONNECTED_ITEM* aItem,
 const KICAD_T aTypes[],
 bool aIgnoreNetcodes ) const
{
 std::vector<BOARD_CONNECTED_ITEM*> rv;
 const auto clusters = m_connAlgo->SearchClusters(
 aIgnoreNetcodes ?
 CN_CONNECTIVITY_ALGO::CSM_PROPAGATE :
 CN_CONNECTIVITY_ALGO::CSM_CONNECTIVITY_CHECK, aTypes,
 aIgnoreNetcodes ? -1 : aItem->GetNetCode() );

 for( auto cl : clusters )
 {
 if( cl->Contains( aItem ) )
 {
 for( const auto item : *cl )
 {
 if( item->Valid() )
 rv.push_back( item->Parent() );
 }
 }
 }

 return rv;
}


const std::vector<BOARD_CONNECTED_ITEM*> CONNECTIVITY_DATA::GetNetItems( int aNetCode,
 const KICAD_T aTypes[] ) const
{
 std::vector<BOARD_CONNECTED_ITEM*> items;
 items.reserve( 32 );

 std::bitset<MAX_STRUCT_TYPE_ID> type_bits;

 for( unsigned int i = 0; aTypes[i] != EOT; ++i )
 {
 wxASSERT( aTypes[i] < MAX_STRUCT_TYPE_ID );
 type_bits.set( aTypes[i] );
 }

 m_connAlgo->ForEachItem( [&]( CN_ITEM& aItem ) {
 if( aItem.Valid() && ( aItem.Net() == aNetCode ) && type_bits[aItem.Parent()->Type()] )
 items.push_back( aItem.Parent() );
 } );

 std::sort( items.begin(), items.end() );
 items.erase( std::unique( items.begin(), items.end() ), items.end() );
 return items;
}


bool CONNECTIVITY_DATA::CheckConnectivity( std::vector<CN_DISJOINT_NET_ENTRY>& aReport )
{
 RecalculateRatsnest();

 for( auto net : m_nets )
 {
 if( net )
 {
 for( const auto& edge : net->GetEdges() )
 {
 CN_DISJOINT_NET_ENTRY ent;
 ent.net = edge.GetSourceNode()->Parent()->GetNetCode();
 ent.a = edge.GetSourceNode()->Parent();
 ent.b = edge.GetTargetNode()->Parent();
 ent.anchorA = edge.GetSourceNode()->Pos();
 ent.anchorB = edge.GetTargetNode()->Pos();
 aReport.push_back( ent );
 }
 }
 }

 return aReport.empty();
}


const std::vector<PCB_TRACK*> CONNECTIVITY_DATA::GetConnectedTracks(
 const BOARD_CONNECTED_ITEM* aItem ) const
{
 auto& entry = m_connAlgo->ItemEntry( aItem );

 std::set<PCB_TRACK*> tracks;
 std::vector<PCB_TRACK*> rv;

 for( CN_ITEM* citem : entry.GetItems() )
 {
 for( CN_ITEM* connected : citem->ConnectedItems() )
 {
 if( connected->Valid() &&
 ( connected->Parent()->Type() == PCB_TRACE_T ||
 connected->Parent()->Type() == PCB_VIA_T ||
 connected->Parent()->Type() == PCB_ARC_T ) )
 tracks.insert( static_cast<PCB_TRACK*> ( connected->Parent() ) );
 }
 }

 std::copy( tracks.begin(), tracks.end(), std::back_inserter( rv ) );
 return rv;
}


void CONNECTIVITY_DATA::GetConnectedPads( const BOARD_CONNECTED_ITEM* aItem,
 std::set<PAD*>* pads ) const
{
 for( CN_ITEM* citem : m_connAlgo->ItemEntry( aItem ).GetItems() )
 {
 for( CN_ITEM* connected : citem->ConnectedItems() )
 {
 if( connected->Valid() && connected->Parent()->Type() == PCB_PAD_T )
 pads->insert( static_cast<PAD*> ( connected->Parent() ) );
 }
 }
}


const std::vector<PAD*> CONNECTIVITY_DATA::GetConnectedPads( const BOARD_CONNECTED_ITEM* aItem )
const
{
 std::set<PAD*> pads;
 std::vector<PAD*> rv;

 GetConnectedPads( aItem, &pads );

 std::copy( pads.begin(), pads.end(), std::back_inserter( rv ) );
 return rv;
}


unsigned int CONNECTIVITY_DATA::GetNodeCount( int aNet ) const
{
 int sum = 0;

 if( aNet < 0 ) // Node count for all nets
 {
 for( const RN_NET* net : m_nets )
 sum += net->GetNodeCount();
 }
 else if( aNet < (int) m_nets.size() )
 {
 sum = m_nets[aNet]->GetNodeCount();
 }

 return sum;
}


unsigned int CONNECTIVITY_DATA::GetPadCount( int aNet ) const
{
 int n = 0;

 for( CN_ITEM* pad : m_connAlgo->ItemList() )
 {
 if( !pad->Valid() || pad->Parent()->Type() != PCB_PAD_T)
 continue;

 PAD* dpad = static_cast<PAD*>( pad->Parent() );

 if( aNet < 0 || aNet == dpad->GetNetCode() )
 n++;
 }

 return n;
}


void CONNECTIVITY_DATA::GetUnconnectedEdges( std::vector<CN_EDGE>& aEdges) const
{
 for( const RN_NET* rnNet : m_nets )
 {
 if( rnNet )
 {
 for( const CN_EDGE& edge : rnNet->GetEdges() )
 aEdges.push_back( edge );
 }
 }
}


static int getMinDist( BOARD_CONNECTED_ITEM* aItem, const wxPoint& aPoint )
{
 switch( aItem->Type() )
 {
 case PCB_TRACE_T:
 case PCB_ARC_T:
 {
 PCB_TRACK* track = static_cast<PCB_TRACK*>( aItem );

 return std::min( GetLineLength( track->GetStart(), aPoint ),
 GetLineLength( track->GetEnd(), aPoint ) );
 }

 default:
 return GetLineLength( aItem->GetPosition(), aPoint );
 }
}


bool CONNECTIVITY_DATA::TestTrackEndpointDangling( PCB_TRACK* aTrack, wxPoint* aPos )
{
 std::list<CN_ITEM*> items = GetConnectivityAlgo()->ItemEntry( aTrack ).GetItems();

 // Not in the connectivity system. This is a bug!
 if( items.empty() )
 {
 wxFAIL_MSG( "track not in connectivity system" );
 return false;
 }

 CN_ITEM* citem = items.front();

 if( !citem->Valid() )
 return false;

 if( aTrack->Type() == PCB_TRACE_T || aTrack->Type() == PCB_ARC_T )
 {
 // Test if a segment is connected on each end.
 //
 // NB: be wary of short segments which can be connected to the *same* other item on
 // each end. If that's their only connection then they're still dangling.

 PCB_LAYER_ID layer = aTrack->GetLayer();
 int accuracy = KiROUND( aTrack->GetWidth() / 2 );
 int start_count = 0;
 int end_count = 0;

 for( CN_ITEM* connected : citem->ConnectedItems() )
 {
 BOARD_CONNECTED_ITEM* item = connected->Parent();

 if( item->GetFlags() & IS_DELETED )
 continue;

 std::shared_ptr<SHAPE> shape = item->GetEffectiveShape( layer );

 bool hitStart = shape->Collide( aTrack->GetStart(), accuracy );
 bool hitEnd = shape->Collide( aTrack->GetEnd(), accuracy );

 if( hitStart && hitEnd )
 {
 if( getMinDist( item, aTrack->GetStart() ) < getMinDist( item, aTrack->GetEnd() ) )
 start_count++;
 else
 end_count++;
 }
 else if( hitStart )
 {
 start_count++;
 }
 else if( hitEnd )
 {
 end_count++;
 }

 if( start_count > 0 && end_count > 0 )
 return false;
 }

 if( aPos )
 *aPos = (start_count == 0 ) ? aTrack->GetStart() : aTrack->GetEnd();

 return true;
 }
 else if( aTrack->Type() == PCB_VIA_T )
 {
 // Test if a via is only connected on one layer

 const std::vector<CN_ITEM*>& connected = citem->ConnectedItems();

 if( connected.empty() )
 {
 if( aPos )
 *aPos = aTrack->GetPosition();

 return true;
 }

 // Here, we check if the via is connected only to items on a single layer
 int first_layer = UNDEFINED_LAYER;

 for( CN_ITEM* item : connected )
 {
 if( item->Parent()->GetFlags() & IS_DELETED )
 continue;

 if( first_layer == UNDEFINED_LAYER )
 first_layer = item->Layer();
 else if( item->Layer() != first_layer )
 return false;
 }

 if( aPos )
 *aPos = aTrack->GetPosition();

 return true;
 }
 else
 {
 wxFAIL_MSG( "CONNECTIVITY_DATA::TestTrackEndpointDangling: unknown track type" );
 }

 return false;
}


const std::vector<BOARD_CONNECTED_ITEM*> CONNECTIVITY_DATA::GetConnectedItemsAtAnchor(
 const BOARD_CONNECTED_ITEM* aItem,
 const VECTOR2I& aAnchor,
 const KICAD_T aTypes[],
 const int& aMaxError ) const
{
 auto& entry = m_connAlgo->ItemEntry( aItem );
 std::vector<BOARD_CONNECTED_ITEM*> rv;
 SEG::ecoord maxErrorSq = (SEG::ecoord) aMaxError * aMaxError;

 for( auto cnItem : entry.GetItems() )
 {
 for( auto connected : cnItem->ConnectedItems() )
 {
 for( auto anchor : connected->Anchors() )
 {
 if( ( anchor->Pos() - aAnchor ).SquaredEuclideanNorm() <= maxErrorSq )
 {
 for( int i = 0; aTypes[i] > 0; i++ )
 {
 if( connected->Valid() && connected->Parent()->Type() == aTypes[i] )
 {
 rv.push_back( connected->Parent() );
 break;
 }
 }

 break;
 }
 }
 }
 }

 return rv;
}


RN_NET* CONNECTIVITY_DATA::GetRatsnestForNet( int aNet )
{
 if ( aNet < 0 || aNet >= (int) m_nets.size() )
 {
 return nullptr;
 }

 return m_nets[ aNet ];
}


void CONNECTIVITY_DATA::MarkItemNetAsDirty( BOARD_ITEM *aItem )
{
 if ( aItem->Type() == PCB_FOOTPRINT_T)
 {
 for( PAD* pad : static_cast<FOOTPRINT*>( aItem )->Pads() )
 m_connAlgo->MarkNetAsDirty( pad->GetNetCode() );
 }
 if (aItem->IsConnected() )
 {
 m_connAlgo->MarkNetAsDirty( static_cast<BOARD_CONNECTED_ITEM*>( aItem )->GetNetCode() );
 }
}


void CONNECTIVITY_DATA::SetProgressReporter( PROGRESS_REPORTER* aReporter )
{
 m_progressReporter = aReporter;
 m_connAlgo->SetProgressReporter( m_progressReporter );
}


const std::vector<CN_EDGE> CONNECTIVITY_DATA::GetRatsnestForItems( std::vector<BOARD_ITEM*> aItems )
{
 std::set<int> nets;
 std::vector<CN_EDGE> edges;
 std::set<BOARD_CONNECTED_ITEM*> item_set;

 for( BOARD_ITEM* item : aItems )
 {
 if( item->Type() == PCB_FOOTPRINT_T )
 {
 FOOTPRINT* footprint = static_cast<FOOTPRINT*>( item );

 for( PAD* pad : footprint->Pads() )
 {
 nets.insert( pad->GetNetCode() );
 item_set.insert( pad );
 }
 }
 else if( auto conn_item = dyn_cast<BOARD_CONNECTED_ITEM*>( item ) )
 {
 item_set.insert( conn_item );
 nets.insert( conn_item->GetNetCode() );
 }
 }

 for( const auto& netcode : nets )
 {
 RN_NET* net = GetRatsnestForNet( netcode );

 for( const CN_EDGE& edge : net->GetEdges() )
 {
 std::shared_ptr<CN_ANCHOR> srcNode = edge.GetSourceNode();
 std::shared_ptr<CN_ANCHOR> dstNode = edge.GetTargetNode();

 BOARD_CONNECTED_ITEM* srcParent = srcNode->Parent();
 BOARD_CONNECTED_ITEM* dstParent = dstNode->Parent();

 bool srcFound = ( item_set.find( srcParent ) != item_set.end() );
 bool dstFound = ( item_set.find( dstParent ) != item_set.end() );

 if ( srcFound && dstFound )
 edges.push_back( edge );
 }
 }

 return edges;
}


const std::vector<CN_EDGE> CONNECTIVITY_DATA::GetRatsnestForPad( const PAD* aPad )
{
 std::vector<CN_EDGE> edges;
 RN_NET* net = GetRatsnestForNet( aPad->GetNetCode() );

 for( const CN_EDGE& edge : net->GetEdges() )
 {
 if( edge.GetSourceNode()->Parent() == aPad || edge.GetTargetNode()->Parent() == aPad )
 edges.push_back( edge );
 }

 return edges;
}


const std::vector<CN_EDGE> CONNECTIVITY_DATA::GetRatsnestForComponent( FOOTPRINT* aComponent, bool aSkipInternalConnections )
{
 std::set<int> nets;
 std::set<const PAD*> pads;
 std::vector<CN_EDGE> edges;

 for( auto pad : aComponent->Pads() )
 {
 nets.insert( pad->GetNetCode() );
 pads.insert( pad );
 }

 for( const auto& netcode : nets )
 {
 const auto& net = GetRatsnestForNet( netcode );

 for( const auto& edge : net->GetEdges() )
 {
 auto srcNode = edge.GetSourceNode();
 auto dstNode = edge.GetTargetNode();

 const PAD* srcParent = static_cast<const PAD*>( srcNode->Parent() );
 const PAD* dstParent = static_cast<const PAD*>( dstNode->Parent() );

 bool srcFound = ( pads.find(srcParent) != pads.end() );
 bool dstFound = ( pads.find(dstParent) != pads.end() );

 if ( srcFound && dstFound && !aSkipInternalConnections )
 {
 edges.push_back( edge );
 }
 else if ( srcFound || dstFound )
 {
 edges.push_back( edge );
 }
 }
 }

 return edges;
}